CN114854630B - Selenium-resistant bacillus and breeding method and application thereof - Google Patents

Abstract

The invention discloses a selenium-resistant bacillus and a breeding method and application thereof, and the preservation number is CGMCC No.24522 and is named as Paramycolatopsis B.Paramycolatopide 1805. In 5mmol/L sodium selenite LB culture medium, the reduction rate of the strain to sodium selenite can reach 65.7%, and the tolerance to sodium selenite is 80mmol/L. The final tolerance of the strain to sodium selenite in liquid and solid plates respectively reaches 190mmol/L and 140mmol/L, and the original tolerance is 2.375 times and 1.75 times. The invention provides a new strain for the microorganism synthesized nano selenium market, and has extremely wide application prospect and industrial value.

Description

Selenium-resistant bacillus and breeding method and application thereof

Technical Field

The invention belongs to a microorganism breeding method and application, and particularly relates to a selenium-resistant bacillus breeding method and application.

Background

Selenium (Se) plays a key role in maintaining the healthy development of animal and plant bodies and preventing and controlling diseases, and has a great benefit, and how to reasonably use selenium becomes a critical problem. The current dietary selenium supplementing method is one of the most effective ways for improving the selenium deficiency condition, and compared with the current chemical method and physical method for synthesizing the selenium simple substance, the biological method has the advantages of green, safety, environmental protection, controllability and the like. The nano-selenium is also the same, and compared with inorganic selenium and organic selenium, the nano-selenium has strong biological activity, low toxicity and easy absorption, and is the safest and reliable way for supplementing selenium at present.

The synthesis method of nano selenium is divided into a chemical method and a biological method. The nano-selenium prepared by the chemical synthesis method has poor stability, and a dispersing agent or a protective agent is required to be added, so that the nano-selenium synthesis process is complex and the production cost is increased. The biological method for preparing the nano-selenium mainly utilizes the reaction of products and selenium salts in the growth and development process of microorganisms (bacteria, fungi, actinomycetes and the like) to prepare the nano-selenium, and the method has mild reaction conditions, and the prepared nano-selenium has high biological activity, smaller size, uniform particle size, strong stability and environmental friendliness, and is a hotspot in the field of synthesizing the nano-selenium at present.

Currently, with the development of the technology level, more and more microorganisms are found to have the efficacy and capability of converting inorganic selenium into nano-selenium, but some problems are also highlighted gradually. At present, related microorganisms are studied, the general tolerance of the microorganisms to high-concentration inorganic selenium is poor, the maximum selenium tolerance concentration of the microorganisms is about 150 mmol/L, the reduction speed of most microorganisms is low, and 48-108 h is basically required to reduce the inorganic selenium into nano-selenium, so that the application of the microorganisms in practical production and life is greatly limited.

Disclosure of Invention

The invention aims to: the invention aims to provide selenium-resistant bacillus.

The invention also aims to provide a breeding method and application of the selenium-resistant bacillus. The technical scheme is as follows: the selenium-resistant bacillus has a preservation number of CGMCC No.24522 and is classified and named as paramycobacillusB. paramycoides 1805 (i.eBacillus paramycoides 1805). The preservation mechanism is as follows: china general microbiological culture Collection center (China Committee for culture Collection); the preservation time is 2022, 03 and 11; the preservation address is: no. 1 and No. 3 of the north cinquefoil of the morning sun area of beijing city.

The breeding method of the selenium-resistant bacillus is characterized by comprising the following steps of: the method comprises the following steps: collecting a sample from selenium-enriched soil, culturing and purifying, inoculating suspension to be detected into a sodium selenate solid LB culture medium, culturing, and selecting a colony with synthesis capability; inoculating the strain into sodium seleniteCulturing in LB medium, collecting supernatant, and measuring OD with ultraviolet spectrophotometer ₅₀₀ The method comprises the steps of carrying out a first treatment on the surface of the The temperature, the pH and the rotating speed are optimized through a response surface to obtainB. paramycoides 1805 optimal growth conditions and reduction conditions.

Further, the saidB. paramycoides1805 sodium selenite with the concentration of 2mmol/L can be fully synthesized into simple substance nano selenium within 24 hours.

The saidB. paramycoides 1805 the efficiency of reducing sodium selenite under the condition of no optimization is 65.7%, and the tolerance performance of the sodium selenite under the condition of solid plate peiyang reaches 80mmol/L.

The saidB. paramycoides 1805 the optimal growth condition is 30 ℃, pH is 6, and rotating speed is 200rmp/min.

The saidB. paramycoides1805 the condition for synthesizing red simple substance nano selenium is 30-40 deg.C, pH 4-7, and rotating speed 100-150 rmp/min.

The size of the synthesized nano selenium is between 100 and 200 nm.

The saidB. paramycoides The optimal conditions for synthesizing the red elemental nano-selenium by 1805, namely temperature, pH and rotating speed, are independent, and the interference is small, so that the operation condition is simple and easy to control.

The saidB. paramycoides The optimal condition for synthesizing the red simple substance nano selenium by 1805 is 37 ℃, the pH is 6, and the rotating speed is 140rmp/min.

The nano selenium has strong antioxidant activity and antibacterial capability.

The saidB. paramycoides 1805 after the adaptive domestication, the maximum tolerance of sodium selenite in the liquid LB culture medium reaches 190mmol/L, and the maximum tolerance of sodium selenite in the solid plate reaches 140mmol/L.

The invention discloses breeding and application of selenium-resistant bacillus. The method comprisesB. paramycoides 1805 is independently screened and identified by the laboratory, and 2mmol/L sodium selenite can be fully synthesized into simple substance nano selenium within 24 hours. The breeding method of the selenium-resistant bacillus is specifically as follows: collecting sample from selenium-rich soil, culturing, purifying, respectively inoculating 100 μl of suspension to be tested into 5mmol/L sodium selenite solid LB culture medium, culturing at 37deg.C, and selectingColonies with synthetic ability within 24 h; inoculating the strain to 2mmol/L sodium selenite LB medium, shake culturing at 37deg.C and 200rmp/min for 24 hr, collecting supernatant, and measuring OD with ultraviolet spectrophotometer ₅₀₀ The method comprises the steps of carrying out a first treatment on the surface of the The temperature, the pH and the rotating speed are optimized through a response surface to obtainB. paramycoides 1805 optimal growth conditions and reduction conditions; for a pair ofB. paramycoides 1805 is subjected to adaptive domestication to increase environmental tolerance, and is foundB. paramycoides 1805 in liquid LB medium tolerance is improved to 190mmol/L, and solid plate tolerance is also improved to 140mmol/L, and the tolerance is higher than the tolerance of most strains on the market at present to sodium selenite.

The beneficial effects are that: compared with the prior art, the invention has the following advantages:

the invention separates and purifies a bacillusB. paramycoides 1805, which has good nano-selenium synthesis efficiency, extremely high sodium selenite tolerance, excellent antioxidation capability, remarkable antibacterial effect and better environmental adaptability, has wide application prospects in the treatment of high-selenium-enriched environments and the industrial scale production of nano-selenium. In 5mmol/L sodium selenite LB culture medium, the reduction rate of the strain to sodium selenite can reach 65.7%, and the tolerance to sodium selenite is 80mmol/L. Through adaptive evolution, the final tolerance of the strain to sodium selenite in liquid and solid plates respectively reaches 190mmol/L and 140mmol/L, and the original tolerance is 2.375 times and 1.75 times. The invention provides a new strain for the microorganism synthesized nano selenium market, and has extremely wide application prospect and industrial value.

Drawings

FIG. 1 is a schematic diagram of a conventional gas turbineB. paramycoides 1805 schematic representation of the evolutionary tree constructed with other bacteria;

FIG. 2 is a schematic diagram of a conventional deviceB. paramycoides 1805 synthesizing an adaptive domestication effect diagram of nano-selenium, wherein the left diagram a-L shows that the adding amount of sodium selenite in a liquid culture medium is 80-190mmol/L, the right diagram a-g shows that the adding amount of sodium selenite in a solid culture medium is 80-140 mmol/L;

FIG. 3 is a schematic diagram of a preferred embodiment of the present inventionB. paramycoides 1805 synthesizing a nano selenium particle size distribution map;

FIG. 4 is a schematic diagram of a preferred embodiment of the present inventionB. paramycoides 1805 synthesizing a nano selenium electron microscope image;

FIG. 5 is a schematic diagram of a preferred embodiment of the present inventionB. paramycoides 1805, synthesizing nano-selenium antioxidant capacity map, wherein DPPH capacity (a) and reduction capacity (b) are eliminated.

Detailed Description

Example 1:B. paramycoides 1805 screening

And (5) collecting the fertile substrate sludge from the Hongze lake culture pond in Huaian city for later use. Weighing 1g of soil, subpackaging into 100ml of LB culture medium, culturing 3 bottles of each soil in an anaerobic and oxygen consumption mode, placing the culture medium at 37 ℃ for shaking culture at 200rmp/min for one week, and observing whether the culture medium becomes turbid or not and whether bacteria grow better or not. Then shaking up on an operation table, sucking a proper amount of upper liquid by using a sterilization pipetting gun, carrying out gradient dilution by using deionized water, respectively taking 0.2ml of each upper liquid, placing into an LB solid culture dish, coating uniformly, and sealing the culture dish by using a sealing film. And after no liquid flows, culturing in an incubator at 37 ℃ for 1-7 d in an inverted mode. The separated microorganisms are purified by plate streaking for a plurality of times, and single colony is picked out and stored in a refrigerator at 4 ℃ by using a slant culture medium for recording. Anaerobic mode is the same, except that liquid paraffin is isolated from air in liquid LB culture medium, static culture is carried out for 7d, and double-layer plate method is adopted in solid plate. After streaking the dishes, the dishes were preserved as described above. And (3) respectively inoculating 100 mu L of to-be-detected bacterial suspension into a 5mmol/L sodium selenite solid LB culture medium plate and a liquid LB culture medium, respectively repeating each bacterial strain in parallel, culturing for 2d at 37 ℃, and selecting bacterial strains capable of synthesizing a red simple substance in 24 h.

Example 2:B. paramycoides 16S rRNA molecular characterization of 1805

The genome extraction kit (bacteria) of the strain adopts a Ezp column type genome DNA extraction kit (Nanjing Zhuz biotechnology Co., ltd.) to extract, namely, the 16SrRNA gene amplification is carried out on a PCR amplification instrument by using the extracted genome DNA as a template and using universal primers 27-F:5'-AGAGTTTGAGTTTGATCMTGGCTCAG-3' and 1492-R5'-AATTACCTTGTTACGACTT-3', wherein the temperature is set to 94 ℃ for 1min, 55 ℃ for 30s, 72 ℃ for 1min, 4 ℃ for heat preservation and 30 cycles. After the PCR amplification, the product is run to verify whether a single band exists or not, and the gel kit is recycled and sent to Shanghai Biotechnology Inc. for sequencing. The resulting sequences were subjected to BLAST alignment via NCBI's GenBank database. And constructing a phylogenetic tree.

Gram staining of bacteria was performed according to Phygene life sciences, purported to a color test kit, and cell morphology was observed using a 100 phase contrast microscope, and was performed according to the Berger manual.

Amplified by a generic objectB. paramycoides The 16srRNA gene of 1805 strain was subjected to BLAST alignment of the sequence, the total length of PCR products amplified by Shanghai Ind Cheng Co was 1450kp, and the sequence was subjected to BLAST alignment by NCBI's GenBank database to construct phylogenetic tree (FIG. 1), and as a result, it was found that bp1805 strain belongs to Bacillus genus (Bacillus) and was compared with itBacillus paramycoidesstrain (MH 542275.1) similarity is 99.97%, and the strain is determined by combining the traditional physiological and biochemical characteristic identification and the 16S rDNA sequence analysis resultsB. paramycoides 1805 is bacillus.

Example 3:B. paramycoides condition optimization of 1805 synthesized nano-selenium

LB medium was prepared, pH was adjusted (2, 4, 6, 8, 10, 12), and the mixture was packed in triangular flasks of 100mL, and autoclaved at 121℃for 15 min. Adding sterile filtered Na into LB culture medium triangular flask in sterile operation table ₂ SeO ₃ The final concentration is 2mmol/L, and the activated seed is inoculated according to the 1 percent of inoculum sizeB. paramycoides1805 bacterial solutions were subjected to shake culture at (0, 50, 100, 150, 200, 250, 300) r/min at (20, 25, 30, 35, 37, 40, 42, 45 ℃) and 3 replicates were set. Culture reactivation under equivalent conditionsB. paramycoides 1805 bacterial liquid is used as a control, 24h is co-cultured, the reduction rate of sodium selenite is measured, and the bacterial liquid is used as the control under the same conditions. Through the above-mentioned optimization of the process,B. paramycoides the optimal growth conditions for 1805 are 30℃and pH 6, 200 r/min.

Example 4:B. paramycoides 1805 synthesized nano-selenium adaptive domestication

Respectively toB. paramycoides1805 liquid culture and fixationAnd (5) carrying out adaptive domestication on the concentration of sodium selenite in the body plate culture. Firstly, sodium selenite is found in a liquid LB culture mediumB. paramycoides1805 initial maximum tolerance is 80mmol/L. Then, the tolerance was repeated 3 times from 80mmol/L, and finally the concentration was increased to 90mmol/L, and the culture was repeated 3 times, and then the operation was continued. As shown in FIG. 2 (left panel), the maximum tolerance of the strain reached 190mmol/L, which is more than twice that of the earliest 80mmol/L, and the tolerance was greatly improved by this method. The adaptive evolution is also started from 80mmol/L in a solid culture medium plate, the tolerance capacity is deepened by repeating for 3 times, the concentration of sodium selenite is gradually increased, and the cyclic operation is performed 3 times each time. Finally, the tolerance of the solid flat sodium selenite reaches 140mmol/L, and the tolerance capacity is doubled, as shown in figure 2 (right graph).

Example 5.B. paramycoides 1805 synthetic nano-selenium characterization

Will beB. paramycoides 1805 is inoculated in LB liquid medium, and sodium selenite is added to make the final concentration of the sodium selenite be 2mmol/L, and shake culture is carried out at 37 ℃ for 24 h. After the color of the fermentation liquor becomes obviously red, centrifuging at 12000rpm/min for 15 min, removing supernatant, centrifuging at 12000rpm for 15 min at high speed, collecting red precipitate, and repeatedly washing for 3 times by using sterile physiological saline to obtain the pure solution of nano selenium. The nano-selenium particle size distribution was determined by DLS particle size analyzer (fig. 3), while its morphology composition was analyzed by SEM (fig. 4).

Example 6.B. paramycoides 1805 analysis of antioxidant capacity of synthesized nano-selenium

Taking outB. paramycoides 1805 synthesizing nano selenium solution 400 mu L and 6 ml of DPPH solution 0.06 mmol/L (DPPH is configured in absolute ethyl alcohol solution) are dissolved in a glass test tube, and the solution is fully vibrated, light is prevented as much as possible during operation, the nano selenium simple substance solution 400 mu L and 6 mL absolute ethyl alcohol are used as sample parameters for zeroing, the solution is fully vibrated, 3 groups of experiments are repeated, and the solution is kept stand for 30 min in a dark place, and is continuously vibrated during the period. OD determination by ultraviolet spectrophotometer ₅₂₀ Wavelength A _{Sample of} Values. In addition, with absolute ethanol solution as reference for zeroing, 400 μl of absolute ethanol is mixed with 0.06 mmol/LDPPH solution of 6 mL, and light shielding is required in the same mannerStanding for 30 min, and measuring OD of the mixed solution ₅₂₀ Absorbance value A _Control . DPPH clearance was also calculated using 1 g/L BHA and BHT as positive controls. Results discoveryB. paramycoides 1805. The DPPH clearance rates of BHA and BHT are 72.79%, 78.9% and 75.45%, respectively, and as can be seen from comparison of FIG. 5 (a), the nano selenium synthesized by the biological method has higher DPPH clearance capacity.

50. Mu.L, 100. Mu.L, 200. Mu.L, 300. Mu.L, 400. Mu.L, 500. Mu.L of the nano-selenium solution were each taken into glass test tubes, and added with deionized water to make up to 0.5. 0.5 mL. Simultaneously, a pipetting gun is used for respectively adding 2.5 ml of mL phosphate buffer solution and 2.5 ml of 1% potassium ferricyanide solution into the test tube, and fully dissolving and vibrating. After the mixture solution was subjected to water bath at 50℃for 20 minutes, 2.5 ml of 10% trichloroacetic acid was added, and the above test tube was allowed to stand at room temperature for 10 minutes. Then, 2.5 mL reaction solutions were taken from each test tube, and 2.5 mL distilled water and 0.5 ml of 0.1% ferric chloride solution were added. After the reaction is carried out for 10 min and the color is obviously changed, the wavelength OD is measured ₇₀₀ And (3) setting the absorbance value by using the operating solution without adding nano selenium. The higher this value indicates the more reducing the sample. BHA and BHT at 0.1. 0.1 mg/mL were used as positive controls. As shown in FIG. 5 (b), the reduction ability of nano-selenium, BHA and BHT was increased with the increase of the concentration of the added sample within a certain range. The more pronounced the effect over time.B. paramycoides 1805 is the strongest in synthesized nano selenium, BHA and BHT are similar in trend, BHA is slightly superior to BHT, in a word, the nano selenium synthesized by the best strain is superior to other two reducing capacities in reducing capacity, and the nano selenium has stronger reducing capacity, so that a foundation is laid for future application.

Sequence listing

<110> Huaiyin institute of technology

<120> selenium-resistant bacillus, and breeding method and application thereof

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atgggtccct ttagcggctg gctcaaaagg ttaccccacc gacttcgggt gttacaaact 60

ctcgtggtgt gacgggcggt gtgtacaagg cccgggaacg tattcaccgc ggcatgctga 120

tccgcgatta ctagcgattc cagcttcatg taggcgagtt gcagcctaca atccgaactg 180

agaacggttt tatgagatta gctccacctc gcggtcttgc agctctttgt accgtccatt 240

gtagcacgtg tgtagcccag gtcataaggg gcatgatgat ttgacgtcat ccccaccttc 300

ctccggtttg tcaccggcag tcaccttaga gtgcccaact taatgatggc aactaagatc 360

aagggttgcg ctcgttgcgg gacttaaccc aacatctcac gacacgagct gacgacaacc 420

atgcaccacc tgtcactctg ctcccgaagg agaagcccta tctctagggt tttcagagga 480

tgtcaagacc tggtaaggtt cttcgcgttg cttcgaatta aaccacatgc tccaccgctt 540

gtgcgggccc ccgtcaattc ctttgagttt cagccttgcg gccgtactcc ccaggcggag 600

tgcttaatgc gttaacttca gcactaaagg gcggaaaccc tctaacactt agcactcatc 660

gtttacggcg tggactacca gggtatctaa tcctgtttgc tccccacgct ttcgcgcctc 720

agtgtcagtt acagaccaga aagtcgcctt cgccactggt gttcctccat atctctacgc 780

atttcaccgc tacacatgga attccacttt cctcttctgc actcaagtct cccagtttcc 840

aatgaccctc cacggttgag ccgtgggctt tcacatcaga cttaagaaac cacctgcgcg 900

cgctttacgc ccaataattc cggataacgc ttgccaccta cgtattaccg cggctgctgg 960

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tgccttggtg agccgttacc tcaccaacta gctaatgcga cgcgggtcca tccataagtg 1260

acagccgaag ccgcctttca atttcgaacc atgcggttca aaatgttatc cggtattagc 1320

cccggtttcc cggagttatc ccagtcttat gggcaggtta cccacgtgtt actcacccgt 1380

ccgccgctaa cttcataaga gcaagctcta atccatcgct cgactggcaa gattgggacc 1440

gcccccgcc 1449

Claims (2)

1. A selenium-resistant bacillus is provided, the preservation number of which is CGMCC No.24522, and the classification name is paramycobacillus Bacillus paramycoides 1805.

2. The use of the selenium tolerant bacillus of claim 1 for synthesizing nano-selenium.

Images